KR100824074B1 - Stent - Google Patents

Abstract

A stent capable of evenly expanding a stenosis part is provided to improve stability and convenience in operation by giving even elastic force and softness to the whole peripheral surface of the stent. A stent capable of evenly expanding a stenosis part includes: a cylindrical band body(B) formed by winding a wire(W) in zigzag to have a peak part(P) and a valley part(V); other band bodies formed in the same shape as the band body, and having valley parts connected to the peak parts of a neighboring band body; and the coupling joint parts(W1) of the peak parts and the valley parts positioned in a symmetric screw-shape in a circumferential direction of the band bodies.

Description

The stent {stent}

1 is a view for explaining an overall structure of a stent according to an embodiment of the present invention.

FIG. 2 is an enlarged view of a main part of a stent according to an embodiment of the present invention. FIG.

FIG. 3 is a view showing a stent body in a developed state to explain a structure of a connection part of a stent according to an embodiment of the present invention.

4 is an enlarged view of a part of FIG. 3 in order to explain a connection position and arrangement of a connection part of the stent according to an embodiment of the present invention in more detail.

FIG. 5 is a schematic view illustrating a state in which connecting nodes are distributed along a longitudinal direction of a stent according to an embodiment of the present invention. Referring to FIG.

The present invention relates to a stent, and more particularly, to a stent that is inserted into a narrowed portion of a lumen of a human body having a narrowed passage, thereby facilitating passage of the lumen.

A medical expansion device, commonly referred to as a stent, is used to expand the stenotic region of the lumen, such as a narrowed vein or esophagus, due to inherited or acquired factors.

Such a stent is inserted into the stenotic region of the lumen by a tubular insertion mechanism such as a catheter, and the stent can be expanded by the self-elastic force.

That is, the stent is formed of a cylindrical elastic body to which left and right band bodies formed by winding a wire in a staggered shape and having a normal peak and a valley are connected to the left and right.

When the wire is wound, the plurality of band bodies are connected to the left and right by the connection nodes wound in a state where the peak portions facing each other and the end points of the valley portion are interdigitated between the band bodies.

The connection node is formed so as to connect a plurality of points along a circumference between the band bodies, and the connection node points are located on the straight line in a direction across the band bodies between the band bodies .

Each of these connecting node points is wound around the four ends of the peak portion and the valley portion, so that the elastic repulsive force greatly acts.

However, in the conventional stent, it is difficult to obtain a uniform elastic repulsive force through the entire outer surface. This is because the connecting node portions connecting the respective band bodies are located on a straight line along the circumference of the stent between the band bodies.

That is, when the longitudinal direction of the stent is taken as a reference, an elastic repulsive force is largely generated between the band bodies formed with the connecting nodes, and a relatively small elastic repulsive force is generated in the remaining portions.

Therefore, it is difficult to secure a uniform expanding force through the entire outer surface of the stent while the stent is inserted into the stenotic region of the lumen.

Further, when the stent is bent to correspond to the bent passage of the lumen, the flexibility between the respective band bodies may be lowered by the connecting nodes located on the straight line, and the folding phenomenon may occur.

Such folding may reduce the passage flow of the lumen, which may be a factor in the occurrence of medical side effects.

In addition, when the conventional stethoscope is inserted into the catheter in a reduced diameter size, the connecting nodes positioned on the straight line between the respective band bodies overlap each other.

In this way, when the connecting members are overlapped with each other between the band bodies, the diameter of the reduced diameter of the stent is increased, so that a catheter having a diameter corresponding thereto must be used.

However, a catheter with a larger diameter can cause a patient's pain to be significantly larger than a catheter with a smaller diameter when inserted into the lumen. In particular, the catheter has a disadvantage in that the catheter is not convenient when used in a narrow lumen.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a stent having uniform elasticity and flexibility on the entire circumferential surface of the stent, .

In order to realize the object of the present invention as described above,

A cylindrical band member formed by winding a wire in a zigzag shape so as to have a peak portion and a valley portion;

And another band body having the same shape as the band body and having valleys connected to the peaks of the adjacent band bodies,

The connecting portions of the peak portions and the valleys provide a stent positioned in a spiral shape with left and right symmetry along the circumferential direction of the band members.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The embodiments of the present invention will be described by those skilled in the art to which the present invention is applicable.

Therefore, the embodiments of the present invention can be modified into various other forms, and therefore, the claims of the present invention are not limited by the embodiments described below.

FIG. 1 is a view showing the entire structure of a stent according to an embodiment of the present invention, and reference numeral 2 indicates a stent body.

The stent body 2 is composed of a plurality of band bodies B as shown in Fig.

The band bodies B are formed of cylindrical elastic bodies formed by winding a wire W in a staggered shape so as to have a normal peak portion P and a valley portion V. [

That is, the plurality of band bodies (B) are sequentially wound by one wire (W), and the stent body (2) is formed in a state where a plurality of the band bodies (B) are connected to each other in the longitudinal direction of the cylinder with reference to FIG.

A connection node W1 is formed between the band bodies B so that the band bodies B are connected in the longitudinal direction of the cylinder by the connection node W1.

As shown in FIG. 2, the connection node W1 is hooked by intersecting the peak portion P and the wire W of the valley portion V facing each other between the band bodies B as shown in the drawing And is formed in a winding-up state.

Each of the connection nodes W1 has a thickness corresponding to the thickness of the three wires W since the peak portions P and the wires W forming the valley portion V are connected to each other in a wound state.

Although the operation of winding the band bodies B connected to the left and right as described above by one wire W to make the stent body 2 is not shown in the drawing, the wire W is staggered (the peak portion and the valley A method using a conventional banding mechanism having bending pins on the outer surface of the cylinder can be used.

The method of forming the stent body 2 by winding the wire W using the banding device as described above can be easily carried out by a person having ordinary skill in the art, and thus a detailed description thereof will be omitted .

Meanwhile, the stent according to an embodiment of the present invention is formed to be positioned at a position where the connection nodes W1 are displaced from each other in the circumferential direction of the respective band bodies B.

This structure is for preventing the connection nodes W1 from overlapping each other between the respective band bodies B when the diameter of the stent body 2 is reduced.

3 and 4 are enlarged views of the stent body 2 in a fully expanded state and a partially enlarged state in which the stent body 2 is unfolded and expanded. The connecting sections W1 are arranged in the same direction as the longitudinal direction of the stent body 2 In a circumferential direction of the band body (B) from the first reference line (L1) of the band body (B).

These connecting nodes W1 are formed such that the peak portions P of the adjacent band bodies B and the end portions of the valleys V when the band bodies B are formed with the wire W The wire W may be formed by winding the wire W in a zigzag fashion so as to be gradually shifted to either one of left and right from the arbitrary first reference line L1 as shown in FIG.

A method of forming the connection node W1 will be described in more detail with reference to FIG.

First, the wire W is wound in a zigzag fashion so that the peak portions P of the first band body B located at the far right side are formed differently from those of FIG. 3, respectively.

Then, the wire W is wound in a zigzag shape again so as to have a valley V connected to the peak portions P of the first band body B, B).

Then, the connection node portions W1 connecting between the two band bodies B are positioned in a state of being displaced from each other along the circumference of the band body B from the arbitrary first reference line L1 .

The stent body 2 may be formed by connecting the plurality of band bodies B in such a connection manner.

The connection nodes W1 may be formed in a locus (for example, a "V" shape or a " V " shape) that gradually shifts in one direction "U" shape).

That is, as shown in FIG. 4, the connecting nodes W1 formed between the two band bodies B are positioned with the left and right sides symmetrical with respect to the arbitrary first reference line L1.

Such a structure can significantly reduce the number of overlapping portions of the connection nodes W1 between the respective band bodies B when the diameter of the outer circumferential surface of the stent body 2 is reduced toward the center have.

For example, with reference to FIG. 4, any second reference lines (L2-1, L2-2, L2-3, L2-4, L2 -5, L2-6, L2- 7) and only two or less numbers.

Therefore, when the diameter of the stent body 2 is reduced, the thickness of the stent body 2 can be reduced by 50% or more as compared with the conventional stent where the connection node points are located straight along the circumference between the band bodies as in the conventional art.

The connection nodes W1 are not limited to the structure in which the left and right sides are symmetrical about the arbitrary first reference line L1 as shown in FIG.

For example, although not shown in the figure, the left and right sides may be formed asymmetrically around the arbitrary first reference line L1.

5, the total length D of the stent main body 2 is set to be approximately equal to the total length D of the stent main body 2, ), The connection points are evenly distributed in a state in which they are mutually offset.

Such a structure may be such that, for example, the connecting node points are uniformly distributed over the entire outer surface of the stent body 2 by points of the connecting node W1, as compared to the normal stents located on a straight line between the band bodies Elastic reaction force and flexibility can be ensured.

In addition, since the diameter size of the stent body 2 can be minimized, the size (diameter) of the catheter used as the means for inserting the stent body 2 into the human body cavity can be made compact.

Particularly, a small-diameter catheter can reduce the pain generated when the catheter contacts the lumen of the human body when inserting the stent body 2 into the human lumen, and the accessibility is improved when the lumen is inserted into the narrow lumen.

When the connection members W1 are rotated about the circumference of the respective band bodies B, the connection points are shifted to either side and then return to the opposite direction in a symmetrical or asymmetrical manner May be repeated one or more times.

Such a structure can be positioned such that the connecting node portions W1 are evenly distributed within the entire length of the stent body 2. [

As described above, according to the present invention, since the connecting nodes for connecting the plurality of band bodies in a cylindrical shape are located in a shifted state so as not to overlap each other between the respective band bodies, It is possible to provide uniform elastic repulsion and flexibility and to suppress the phenomenon of folding when the stent is bent.

Particularly, when the connecting nodes are located at the positions where they are shifted from each other, the number (two or less) of the connecting nodes between the respective band bodies can be minimized when the diameter of the stent is reduced.

Therefore, as compared with the conventional stents positioned on a straight line, the size of the diameter of the reduced diameter of the stent can be drastically reduced so that the connecting node points between the band bodies can overlap each other as in the conventional art.

Accordingly, the present invention can expand the stenotic region evenly when expanding the stenosis region of the lumen of the human body, and can be performed with a catheter of a compact size having a small diameter, so that satisfactory procedure compatibility and convenience of operation .

Claims (4)

A cylindrical band member formed by winding a wire in a zigzag shape so as to have a peak portion and a valley portion; And another band body having the same shape as the band body and having valleys connected to the peaks of the adjacent band bodies, Wherein the connecting portions of the peak portions and the valley portions are located in a spiral shape with left and right symmetrical along the circumferential direction of the band bodies. The method according to claim 1, The connection nodes, Wherein when the diameter of the band bodies is reduced so that the band bodies are dislocated toward the central portion, the stent is positioned so that two or more of the band bodies do not overlap with each other. The method according to claim 1, The connection nodes, Wherein the stent is formed so as to be repeated one or more times in a state of being shifted to either side between the respective band bodies and returning symmetrically or asymmetrically to the opposite direction. A cylindrical band member formed by winding a wire in a zigzag shape so as to have a peak portion and a valley portion; And another band body having the same shape as the band body and having valleys connected to the peaks of the adjacent band bodies, Wherein the connection portions of the peak portions and the valleys are located in a spiral shape with left and right asymmetric along the circumferential direction of the band members.

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